IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0934334
(2004-09-03)
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발명자
/ 주소 |
- Du,Hung T.
- Verbrugge,Brandon L.
- Ortt,Earl M.
- Agnes,Michael J.
- Stone,John C.
- Zemlock,Michael A.
- Kusmierski,Robert G.
- Smith,David J.
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출원인 / 주소 |
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
20 인용 특허 :
142 |
초록
▼
An electric motor, power tool using the electric motor, and method of making the electric motor includes making a stator by separately forming pole pieces, return path pieces and field coils. The field coils are placed over necks of the pole path pieces and the return path pieces are affixed to the
An electric motor, power tool using the electric motor, and method of making the electric motor includes making a stator by separately forming pole pieces, return path pieces and field coils. The field coils are placed over necks of the pole path pieces and the return path pieces are affixed to the pole pieces. An armature having an outside diameter of at least 0.625 the outside diameter of the stator is placed in the stator. In an aspect, the field coils are formed so that they extend beyond pole tips of the pole pieces.
대표청구항
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What is claimed is: 1. An electric motor, comprising: a. a stator having pole pieces on which field coils are disposed and return path pieces mated to the pole pieces, the stator having an outside diameter; and b. an armature having an outside diameter that is at least 0. 625 of the outside diamet
What is claimed is: 1. An electric motor, comprising: a. a stator having pole pieces on which field coils are disposed and return path pieces mated to the pole pieces, the stator having an outside diameter; and b. an armature having an outside diameter that is at least 0. 625 of the outside diameter of the stator. 2. The motor of claim 1 wherein the field coils extend beyond pole tips of the pole pieces on which they are disposed. 3. The motor of claim 1 including insulating sleeves in which the field coils are received, the insulating sleeves disposed between the field coils and surfaces of the pole pieces and return path pieces that are adjacent the field coils. 4. The motor of claim 1 wherein the pole pieces and return path pieces have mating features that are deformed together to secure the return path pieces to the pole pieces. 5. The motor of claim 1 wherein each pole piece has a neck with opposed receiving pockets therein, each return path piece having a finger at each end which is received in a respective pocket of a pole piece and portions of the necks of the pole pieces having the receiving pockets and the fingers deformed together to secure the pole pieces to the return path pieces. 6. The motor of claim 1 including an insulating slot liner made of a layer of insulation material with at least one of a B-stage thermosetting adhesive and a thermoplastic adhesive on at least one side wrapped around each portion of each field coil disposed between one of the pole pieces and one of the return path pieces mated to that pole piece, the adhesive activated during assembly of the stator and bonding the layer of insulation material to that field coil and those pole and return path pieces to secure them together. 7. The motor of claim 1 wherein lengths of coil ends of each field coil are insulated with one of TFE and PTFE tubing to provide lead wires for each field coil. 8. The motor of claim 1 wherein the motor is thermally balanced. 9. The motor of claim 1 wherein the field coils include windings of at least two different sizes of wires. 10. The motor of claim 1 wherein the field coils are encapsulated in a thermally conductive thermoset plastic. 11. An electric motor, comprising: a. a stator having pole pieces on which field coils are disposed and return path pieces mated to the pole pieces, the field coils extending beyond pole tips of the pole pieces on which they are disposed, the stator having an outside diameter; and b. an armature having an outside diameter that is at least 0. 625 of the outside diameter of the stator. 12. The motor of claim 11 wherein the field coils have an included angle of at least 110% of an included angle of the pole tips. 13. The motor of claim 11 wherein the field coils have an included angle of at least 125% of an included angle of the pole tips. 14. The motor of claim 11 wherein the field coils have an included angle of at least 140% of an included angle of the pole tips. 15. The motor of claim 11 wherein the field coils have an included angle of at least 155% of an included angle of the pole tips. 16. The motor of claim 11 wherein the field coils have a packing factor of at least 60%. 17. The motor of claim 11 wherein the field coils have a packing factor of at least 70%. 18. The motor of claim 11 wherein the field coils have a packing factor of at least 80%. 19. The motor of claim 11 wherein the field coils have a packing factor of at least 85%. 20. The motor of claim 11 wherein the field coils have a packing factor of at least 60% and an included angle of at least 110% of an included angle of the pole tips. 21. The motor of claim 11 wherein the field coils have a packing factor of at least 70% and an included angle of at least 110% of an included angle of the pole tips. 22. The motor of claim 11 wherein the field coils have a packing factor of at least 80% and an included angle of at least 110% of an included angle of the pole tips. 23. The motor of claim 11 wherein the field coils have a packing factor of at least 85% and an included angle of at least 110% of an included angle of the pole tips. 24. The motor of claim 11 wherein the field coils have a packing factor of at least 60% and an included angle of at least 125% of an included angle of the pole tips. 25. The motor of claim 11 wherein the field coils have a packing factor of at least 70% and an included angle of at least 125% of an included angle of the pole tips. 26. The motor of claim 11 wherein the field coils have a packing factor of at least 80% and an included angle of at least 125% of an included angle of the pole tips. 27. The motor of claim 11 wherein the field coils have a packing factor of at least 85% and an included angle of at least 125% of an included angle of the pole tips. 28. The motor of claim 11 wherein the field coils have a packing factor of at least 60% and an included angle of at least 140% of an included angle of the pole tips. 29. The motor of claim 11 wherein the field coils have a packing factor of at least 70% and an included angle of at least 140% of an included angle of the pole tips. 30. The motor of claim 11 wherein the field coils have a packing factor of at least 80% and an included angle of at least 140% of an included angle of the pole tips. 31. The motor of claim 11 wherein the field coils have a packing factor of at least 85% and an included angle of at least 140% of an included angle of the pole tips. 32. The motor of claim 11 wherein the field coils have a packing factor of at least 60% and an included angle of at least 155% of an included angle of the pole tips. 33. The motor of claim 11 wherein the field coils have a packing factor of at least 70% and an included angle of at least 155% of an included angle of the pole tips. 34. The motor of claim 11 wherein the field coils have a packing factor of at least 80% and an included angle of at least 155% of an included angle of the pole tips. 35. The motor of claim 11 wherein the field coils have a packing factor of at least 85% and an included angle of at least 155% of an included angle of the pole tips. 36. The motor of claim 11 including insulating sleeves in which the field coils are received, the insulating sleeves disposed between the field coils and surfaces of the pole pieces and return path pieces that are adjacent the field coils. 37. The motor of claim 11 wherein the pole pieces and return path pieces have mating features that are deformed together to secure the return path pieces to the pole pieces. 38. The motor of claim 11 wherein each pole piece has a neck with opposed receiving pockets therein, each return path piece having a finger at each end which is received in a respective pocket of a pole piece and portions of the necks of the pole pieces having the receiving pockets and the fingers deformed together to secure the pole pieces to the return path pieces. 39. The motor of claim 11 including an insulating slot liner made of a layer of insulation material with at least one of a B-stage thermosetting adhesive and a thermoplastic adhesive on at least one side wrapped around each portion of each field coil disposed between one of the pole pieces and one of the return path pieces mated to that pole piece, the adhesive activated during assembly of the stator and bonding the layer of insulation material to that field coil and those pole and return path pieces to secure them together. 40. The motor of claim 11 wherein lengths of coil ends of each field coil are insulated with one of TFE and PTFE tubing to provide lead wires for each field coil. 41. The motor of claim 11 wherein at least one of the pole pieces and return path pieces are made of insulated iron powder. 42. The motor of claim 11 wherein the motor is thermally balanced. 43. The motor of claim 11 wherein the field coils include windings of at least two different sizes of wires. 44. A hand-held power tool, comprising: a. a housing; and b. a motor disposed in the housing, the motor including: i. a stator having pole pieces on which field coils are disposed and return path pieces mated to the pole pieces, the stator having an outside diameter; and ii. an armature having an outside diameter that is at least 0. 625 of the outside diameter of the stator. 45. The power tool of claim 44 wherein the field coils extend beyond tips of the pole pieces on which they are disposed. 46. The power tool of claim 44 including insulating sleeves in which the field coils are received, the insulating sleeves disposed between the field coils and surfaces of the pole pieces and return path pieces that are adjacent the field coils. 47. The power tool of claim 44 wherein the pole pieces and return path pieces have mating features that are deformed together to secure the return path pieces to the pole pieces. 48. The power tool of claim 44 wherein each pole piece has a neck with opposed receiving pockets therein, each return path piece having a finger at each end which is received in a respective pocket of a pole piece and portions of the necks of the pole pieces having the receiving pockets and the fingers deformed together to secure the pole pieces to the return path pieces. 49. The power tool of claim 44 including an insulating slot liner made of a layer of insulation material with at least one of a B-stage thermosetting adhesive and a thermoplastic adhesive on at least one side wrapped around each portion of each field coil disposed between one of the pole pieces and one of the return path pieces mated to that pole piece, the adhesive activated during assembly of the stator and bonding the layer of insulation material to that field coil and those pole and return path pieces to secure them together. 50. The power tool of claim 44 wherein lengths of coil ends of each field coil are insulated with one of TFE and PTFE tubing to provide lead wires for each field coil. 51. The power tool of claim 44 wherein the motor is thermally balanced. 52. The power tool of claim 44 wherein the field coils include windings of at least two different sizes of wires. 53. A hand-held power tool, comprising: a. a housing; b. a motor disposed in the housing; c. the motor including: i. a stator having pole pieces on which field coils are disposed and return path pieces mated to the pole pieces, the field coils extending beyond pole tips of the pole pieces on which they are disposed, the stator having an outside diameter; and ii. an armature having an outside diameter that is at least 0. 625 of the outside diameter of the stator. 54. The power tool of claim 53 wherein the field coils have an included angle of at least 110% of an included angle of the pole tips. 55. The power tool of claim 53 wherein the field coils have an included angle of at least 125% of an included angle of the pole tips. 56. The power tool of claim 53 wherein the field coils have an included angle of at least 140% of an included angle of the pole tips. 57. The power tool of claim 53 wherein the field coils have an included angle of at least 155% of an included angle of the pole tips. 58. The power tool of claim 53 wherein the field coils have a packing factor of at least 60%. 59. The power tool of claim 53 wherein the field coils have a packing factor of at least 70%. 60. The power tool of claim 53 wherein the field coils have a packing factor of at least 80%. 61. The power tool of claim 53 wherein the field coils have a packing factor of at least 85%. 62. The power tool of claim 53 wherein the field coils have a packing factor of at least 60% and an included angle of at least 110% of an included angle of the pole tips. 63. The power tool of claim 53 wherein the field coils have a packing factor of at least 70% and an included angle of at least 110% of an included angle of the pole tips. 64. The power tool of claim 53 wherein the field coils have a packing factor of at least 80% and an included angle of at least 110% of an included angle of the pole tips. 65. The power tool of claim 53 wherein the field coils have a packing factor of at least 85% and an included angle of at least 110% of an included angle of the pole tips. 66. The power tool of claim 53 wherein the field coils have a packing factor of at least 60% and an included angle of at least 125% of an included angle of the pole tips. 67. The power tool of claim 53 wherein the field coils have a packing factor of at least 70% and an included angle of at least 125% of an included angle of the pole tips. 68. The power tool of claim 53 wherein the field coils have a packing factor of at least 80% and an included angle of at least 125% of an included angle of the pole tips. 69. The power tool of claim 53 wherein the field coils have a packing factor of at least 85% and an included angle of at least 125% of an included angle of the pole tips. 70. The power tool of claim 53 wherein the field coils have a packing factor of at least 60% and an included angle of at least 140% of an included angle of the pole tips. 71. The power tool of claim 53 wherein the field coils have a packing factor of at least 70% and an included angle of at least 140% of an included angle of the pole tips. 72. The power tool of claim 53 wherein the field coils have a packing factor of at least 80% and an included angle of at least 140% of an included angle of the pole tips. 73. The power tool of claim 53 wherein the field coils have a packing factor of at least 85% and an included angle of at least 140% of an included angle of the pole tips. 74. The power tool of claim 53 wherein the field coils have a packing factor of at least 60% and an included angle of at least 155% of an included angle of the pole tips. 75. The power tool of claim 53 wherein the field coils have a packing factor of at least 70% and an included angle of at least 155% of an included angle of the pole tips. 76. The power tool of claim 53 wherein the field coils have a packing factor of at least 80% and an included angle of at least 155% of an included angle of the pole tips. 77. The power tool of claim 53 wherein the field coils have a packing factor of at least 85% and an included angle of at least 155% of an included angle of the pole tips. 78. The power tool of claim 53 including insulating sleeves in which the field coils are received, the insulating sleeves disposed between the field coils and surfaces of the pole pieces and return path pieces that are adjacent the field coils. 79. The power tool of claim 53 wherein the pole pieces and return path pieces have mating features that are deformed together to secure the return path pieces to the pole pieces. 80. The power tool of claim 53 wherein each pole piece has a neck with opposed receiving pockets therein, each return path piece having a finger at each end which is received in a respective pocket of a pole piece and portions of the necks of the pole pieces having the receiving pockets and the fingers deformed together to secure the pole pieces to the return path pieces. 81. The power tool of claim 53 including an insulating slot liner made of a layer of insulation material with at least one of a B-stage thermosetting adhesive and a thermoplastic adhesive on at least one side wrapped around each portion of each field coil disposed between one of the pole pieces and one of the return path pieces mated to that pole piece, the adhesive activated during assembly of the stator and bonding the layer of insulation material to that field coil and those pole and return path pieces to secure the together. 82. The power tool of claim 53 wherein lengths of coil ends of each field coil are insulated with one of TFE and PTFE tubing to provide lead wires for each field coil. 83. The power tool of claim 48 wherein at least one of the pole pieces and return path pieces are made of insulated iron powder. 84. The power tool of claim 53 wherein the motor is thermally balanced. 85. The power tool of claim 53 wherein the field coils include windings of at least two different sizes of wires. 86. An electric motor of a predetermined frame size having increased power compared to a needle wound motor of the same frame size, comprising: a. a stator having pole pieces on which field coils are disposed and return path pieces mated to the pole pieces, the field coils extending beyond pole tips of the pole pieces on which they are disposed, the stator having an outside diameter; b. an armature having an outside diameter that is at least 0. 625 of the outside diameter of the stator; and c. the field coils formed to provide the motor with a maximum power output at a desired speed that is at least ten percent greater than a maximum power output at the desired speed of the needle wound motor of the same frame size. 87. The motor of claim 86 wherein the electric motor has a 55 mm frame size and a maximum power output at 38,000 rpm of at least 1000 watts. 88. The motor of claim 86 wherein the electric motor has a 59 mm frame size and a maximum power output at 38,000 rpm of at least 1250 watts. 89. The motor of claim 86 wherein the electric motor has a 59 mm frame size and a maximum power output at 38,000 rpm of at least 1600 watts. 90. The motor of claim 86 wherein the field coils have an included angle of at least 110% of an included angle of the pole tips and a packing factor of at least 60%. 91. The motor of claim 86 wherein the field coils have an included angle of at least 125% of an included angle of the pole tips and a packing factor of at least 60%. 92. The motor of claim 86 wherein the field coils have an included angle of at least 145% of an included angle of the pole tips and a packing factor of at least 60%. 93. The motor of claim 86 wherein the field coils have an included angle of at least 155% of an included angle of the pole tips and a packing factor of at least 60%. 94. The motor of claim 86 wherein the field coils have an included angle of at least 110% of an included angle of the pole tips and a packing factor of at least 70%. 95. A hand-held power tool, comprising: a. a housing; b. a motor of a predetermined frame size disposed in the housing, the motor having increased power compared to a needle wound motor of the same frame size, the motor including: i. a stator having pole pieces on which field coils are disposed and return path pieces mated to the pole pieces, the field coils extending beyond pole tips of the pole pieces on which they are disposed, the stator having an outside diameter; ii. an armature having an outside diameter that is at least 0. 625 of the outside diameter of the stator; and iii. the field coils formed to provide the motor with a maximum power output at a desired speed that is at least ten percent greater than a maximum power output at a desired speed of the needle wound motor of the same frame size. 96. The power tool of claim 95 wherein the electric motor has a 55 mm frame size and a maximum power output at 38,000 rpm of at least 1000 watts. 97. The power tool of claim 95 wherein the electric motor has a 59 mm frame size and a maximum power output at 38,000 rpm of at least 1250 watts. 98. The power tool of claim 95 wherein the electric motor has a 59 mm frame size and a maximum power output at 38,000 rpm of at least 1600 watts. 99. The power tool of claim 95 wherein the field coils have an included angle of at least 110% of an included angle of the pole tips and a packing factor of at least 60%. 100. The power tool of claim 95 wherein the field coils have an included angle of at least 125% of an included angle of the pole tips and a packing factor of at least 60%. 101. The power tool of claim 95 wherein the field coils have an included angle of at least 145% of an included angle of the pole tips and a packing factor of at least 60%. 102. The power tool of claim 95 wherein the field coils have an included angle of at least 155% of an included angle of the pole tips and a packing factor of at least 60%. 103. The power tool of claim 95 wherein the field coils have an included angle of at least 110% of an included angle of the pole tips and a packing factor of at least 70%.
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